KR20200110125A - Precast concrete girder for used by continuous construction method - Google Patents

Abstract

The present invention relates to a method of constructing precast concrete pillars and beams installed on the site after being manufactured in a factory previously. In a process of installing the precast concrete beams between the precast concrete pillars, an end unit of a beam connecting rebar fastened with a beam connecting ironwork installed on an end unit of the precast concrete beams is inserted into and fixed in the precast concrete pillars. In a process of installing the precast concrete pillars on an upper layer on the precast concrete pillars on a lower layer, at least some of the rebars protruding towards an upper side of the precast concrete pillars on a lower layer are fastened with the pillar connecting ironwork installed on a lower side of the precast concrete pillars on an upper layer. The precast concrete pillars and the precast concrete beams are constructed without performing the bonding unit concrete placement and the topping concrete placement in the process of installing the precast concrete beams. The beam connecting ironwork is a structure with an empty inside and an opened upper surface, and the beam connecting rebar is inserted into the penetrating hole formed on an end unit. With an end unit of the beam connecting rebar inserted into the precast concrete pillars, a nut is fastened with a screw thread formed on a surface of the beam connecting rebar, thereby fastening the beam connecting rebar with the beam connecting rebar. The pillar connecting ironwork is a structure with an empty inside and a part of its side surface opened towards an external surface of the precast concrete pillars. An end unit of the rebar of the precast concrete pillars on a lower layer is inserted into the penetrating hole formed on a lower end. A nut is fastened with a screw thread formed on a surface of the rebar of the precast concrete pillars on a lower layer, thereby fastening the rebar of the precast concrete pillars on a lower layer with the pillar connecting ironwork. According to the present invention, the time for placement and curing of concrete is greatly reduced, thereby reducing the whole process time.

Description

Precast concrete beam for continuous construction {PRECAST CONCRETE GIRDER FOR USED BY CONTINUOUS CONSTRUCTION METHOD}

The present invention relates to precast concrete columns and beams, and a construction method using the same, and more particularly, to a method for continuously constructing precast concrete columns and beams.

In general, the precast concrete construction method means that pillars, beams, and slabs, which are the main components of a building, are manufactured in the form of unit units at the factory in advance, and these precast units are brought into the site and simply assembled or partially poured. It is a method of constructing a building by doing it.

This precast concrete method has the advantage of minimizing field work, improving construction efficiency, reducing construction period significantly, and ensuring a certain quality. Therefore, in recent years, the number of buildings constructed by the precast concrete method is increasing rapidly.

12 shows a state in which precast concrete columns and beams are constructed in multiple layers by a conventional method.

The conventional process of constructing precast concrete columns and beams in multiple layers based on FIG. 12 will be described with respect to the process of installing the upper precast concrete columns 200 on the lower precast concrete columns 100, and In the case of forming a structure, the following method is repeated.

Conventionally, before installing the upper precast concrete pillar 200 on the lower precast concrete pillar 100, a precast concrete beam 300 connected to the lower precast concrete pillar 100 is installed, and the joint concrete The topping concrete 400 was poured at the site and completely hardened, and then an upper precast concrete column 200 was installed thereon.

At this time, after the on-site casting process for one floor is completed, the next floor pillars must be installed, and it takes about 1 week each to install the upper precast concrete pillars on top of one precast concrete pillar. Therefore, there is a problem that a lot of time is required when configuring a multilayer.

Republic of Korea Patent Registration 10-0937745

An object of the present invention is to provide a continuous construction method capable of continuously constructing only precast concrete columns and beams first and precast concrete columns and beams used therein as to solve the problems of the prior art.

The continuous construction method of precast concrete pillars and beams according to the present invention for achieving the above object is a method of constructing precast concrete pillars and beams manufactured in advance at the site and installed at the site, between precast concrete pillars. In the process of installing precast concrete beams in the precast concrete beam, the end of the beam connecting reinforcing bar fastened to the prosthesis hardware installed at the end of the precast concrete beam is inserted into the precast concrete column and fixed. In the process of installing the cast concrete column, by fastening at least some of the reinforcing bars protruding to the upper part of the precast concrete column on the lower floor and the column connecting hardware installed under the precast concrete column on the upper floor, Precast concrete columns and precast concrete beams are constructed without performing concrete pouring and topping concrete pouring at the junction, and the beam connecting hardware is a structure with an empty inside and an open top surface. In a state in which the connecting reinforcing bar is inserted and the end of the beam connecting reinforcing bar is inserted into the precast concrete column, a nut is fastened to the thread formed on the surface of the beam connecting reinforcing bar to connect the beam connecting reinforcing bar and the prosthesis, and the column connecting hardware Is a structure in which the inside is empty and a part of the side is open to the outer surface of the precast concrete column, and the rebar end of the lower precast concrete column is inserted into the through hole formed at the bottom, and is formed on the rebar surface of the lower precast concrete column. It is characterized in that by fastening a nut to the screw thread to fasten the reinforcing bar of the lower precast concrete column and the column connecting hardware.

In the process of fastening the prosthesis reinforcing bar and the prosthesis, it is preferable that nuts are fastened to each of both sides with the prosthesis interposed therebetween.

The end of the beam connection reinforcing bar may be configured to be fitted and fixed to a coupler inserted into a precast concrete column.

In the process of fastening the reinforcing bars of the lower precast concrete column and the column connecting hardware, it is preferable that nuts are fastened to each of both sides with the column connecting hardware interposed therebetween.

A protrusion protruding a predetermined distance is formed in the center of the end of the precast concrete beam, and at least a part of the prosthesis is installed on the protrusion, and in the process of installing the precast concrete beam between the precast concrete pillars, the precast concrete pillar It is preferable to insert a shim between the and the protrusion.

A precast concrete column according to another form of the present invention is a precast concrete column manufactured in advance in a factory and installed in the field, the column body having a bracket on which the end of the precast concrete beam is raised; Reinforcing bars installed perpendicular to the pillar body and exposed at a portion of the upper portion; One or more sleeves installed at the lower end of the pillar body and into which some of the reinforcing bars exposed to the upper portion of the other precast concrete pillars may be inserted; And one that is installed at the lower end of the pillar body, the inside is empty, a part of the side is open to the outer surface of the pillar body, and a through hole is formed at the lower end, so that some of the reinforcing bars exposed to the top of the other precast concrete pillar can be inserted. Including the above column connection hardware, the reinforcing bars and the positions of the sleeve and the column connection hardware correspond to each other, and the reinforcement installed at a position corresponding to the column connection hardware is characterized in that at least part of the thread is formed.

It is preferable that the flat cross-section of the column body is a square, the column connection hardware is at least four, and the column connection hardware is located at four corners of the flat cross-section of the column body.

It is preferable that the direction in which the column connecting hardware is opened to the outer surface of the column body is a corner direction of the flat end surface of the column body.

It is preferable that a through hole is formed at an upper end of the column connection hardware, and a nut is fastened and fixed with the lower end of the reinforcing bar inserted into the through hole.

An end portion is fastened to a side surface of the pillar connection hardware, and the remaining portion may further include a fixing bolt positioned on the pillar body.

It is preferable that the column connecting hardware is located inside a predetermined distance than the outer surface of the column body.

It is preferable to further include a coupler that is inserted and installed above a predetermined interval of the bracket and can be fixed by inserting a reinforcing bar.

According to another form of the present invention, the precast concrete beam, as a precast concrete beam manufactured in advance in a factory and installed in the field, a beam body made long in the horizontal direction; Reinforcing bars installed horizontally on the beam body and partially exposed at both ends; A prosthesis connecting hardware installed at both ends of the beam body, the interior is empty, the upper surface is opened to the outer surface of the beam body, and a through hole is formed at the end thereof; And it characterized in that it comprises a beam connecting reinforcement positioned in the through hole.

A plurality of through-holes are formed at the end of the prosthesis, and a reinforcing bar is inserted into each through-hole, and an intermediate plate for dividing the space in the length direction of the precast concrete beam is installed in the inner space of the prosthesis. desirable.

It is preferable that a protrusion protruding a predetermined distance is formed in the center of both ends of the beam body, and at least a part of the prosthesis is installed on the protrusion.

It is preferable that the end of the prosthesis is located inside a predetermined distance than the end of the protrusion.

It is preferable that the beam body further includes an extension portion extending in a horizontal direction at both ends of the beam body, and the extension portion is formed only on one of the edge of both ends of the beam body, so that the end portion is in an L-shaped shape.

The length of the reinforcing bar exposed to the side where the extension is not formed may be shorter than that of the reinforcing bar exposed at the side where the extension portion is formed, and the length may be extended by a coupler.

The coupler may further include an auxiliary coupler that has a thread formed therein, is fastened with a thread formed at the ends of the connected reinforcing bars to extend the reinforcing bar, and has a thread formed therein to further screw-fasten both sides of the coupler.

The present invention configured as described above, by continuously first constructing the precast concrete pillars and beams, and pouring the joint concrete and topping concrete later, so that the precast concrete pillars and beams are not constructed during the time the concrete is cured by the on-site pouring of each floor. There is an effect that can solve the problem that was not possible.

In addition, compared to the prior art in which the joint concrete and topping concrete are placed separately for each floor, the time required for the entire concrete site placement and curing is greatly reduced, thereby greatly reducing the overall process time.

1 is a cross-sectional view of a precast concrete column according to an embodiment of the present invention, FIG. 2 is a view for explaining the arrangement of reinforcing bars, and FIG. 3 is an enlarged view of the column connecting hardware in FIG. 1.
4 is a cross-sectional view for explaining the installation direction of the column connecting hardware installed on the precast concrete column according to an embodiment of the present invention.
5 is a view for explaining a precast concrete beam according to an embodiment of the present invention.
6 is an enlarged view of the end of a precast concrete beam.
7 is a view for explaining a process of constructing precast concrete columns and beams according to an embodiment of the present invention.
8 is a view for explaining a state in which a precast concrete beam is fastened to a precast concrete column according to an embodiment of the present invention.
9 is a view for explaining a state in which precast concrete columns are fastened to each other according to an embodiment of the present invention.
10 is a view for explaining a method of filling the non-shrinkable mortar in the column connecting hardware of this embodiment.
11 is an enlarged view illustrating a connection of the reinforcing beams of precast concrete beams according to an embodiment of the present invention with a coupler.
12 shows a state in which precast concrete columns and beams are constructed in multiple layers by a conventional method.

An embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

However, the embodiments of the present invention may be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The shapes and sizes of elements in the drawings may be exaggerated for clearer description, and elements indicated by the same reference numerals in the drawings are the same elements.

And throughout the specification, when a part is "connected" to another part, this includes not only the case of being "directly connected", but also the case of being "electrically connected" with another element interposed therebetween. In addition, when a part "includes" or "includes" a certain component, it means that other components are not excluded and other components may be further included or provided unless otherwise specified. do.

In addition, terms such as "first" and "second" are used to distinguish one component from other components, and the scope of the rights is not limited by these terms. For example, a first component may be referred to as a second component, and similarly, a second component may be referred to as a first component.

1 is a cross-sectional view of a precast concrete column according to an embodiment of the present invention, FIG. 2 is a view for explaining the arrangement of reinforcing bars, and FIG. 3 is an enlarged view of the column connecting hardware in FIG. 1. 4 is a cross-sectional view for explaining the installation direction of the column connecting hardware installed on the precast concrete column according to an embodiment of the present invention.

The precast concrete column is a column that is applied to the precast reinforced concrete construction method that is manufactured in advance at the factory and installed in the field. The precast concrete construction method is a construction method in which pre-fabricated columns and beams are installed and combined on site, and forms for columns and beams are not erected on the site, and some cast-in-place concrete is poured in the process of combining columns and beams. . The precast concrete column 1000 of this embodiment shown includes a column body 1100 and two types of column reinforcement 1200 and two types of lower coupling portions 1300.

The column body 1100 is a body of a precast concrete column manufactured with reinforcing bars inside, except that a bracket 1120 protruding to the side is formed in the middle to install a precast concrete beam, and the cross section is square. And the configuration of the precast concrete column can be applied without limitation.

The column reinforcement 1200 is vertically inserted into the column body 1100 in the longitudinal direction so that at least a portion thereof is exposed upwards of the column body 1100, and the precast concrete column of the present embodiment uses two types of reinforcement. A first reinforcing bar 1220 for connecting a general splice sleeve and a second reinforcing bar 1240 having a threaded thread for bolt connection are used together, and as shown in FIG. The column reinforcement 1200 is arranged in a square shape. At this time, the second reinforcing bar 1240 is disposed at a portion corresponding to the corner of the square. The number and arrangement of the reinforcing bars is not limited thereto, but the shape of the reinforcing bar applied to the reinforcing bars disposed at the corners of the square, which is the cross-sectional shape of the precast concrete column, is specified as the second reinforcing bar 1240. The second reinforcing bar 1240 may have a thread formed on the entire surface, but is not limited thereto, and the thread may be formed only in a portion for screwing. At this time, at least a portion protruding to the upper portion must be formed with a thread, and in this embodiment, a thread for coupling the column connecting hardware 1340 is formed at the lower end. In addition, in the length exposed to the upper portion of the column body 1100, the first reinforcing bar 1220 is exposed relatively longer, and the second reinforcing bar 1240 is exposed relatively shorter.

The lower coupling part 1300 is a part for connecting the multi-layered columns in the form of a continuous reinforcement by combining reinforcing columns exposed upward of the columns located below. Conventionally, all the lower coupling portions 1300 were composed of sleeves, but the present invention is characterized in that the connection by the sleeve and screw connection by the column connecting hardware are simultaneously applied. First, a sleeve 1320 as in the prior art is formed at a position corresponding to the first reinforcing bar 1220 for connecting the splice sleeve, and a column connecting hardware 1340 is installed at a position corresponding to the second reinforcing bar 1240.

The column connecting hardware 1340 is installed at the corner of the column body 1100, has an empty inside, and has a box or basket shape with at least one open to the outside of the column body 1100. As shown, the column connecting hardware 1340 of this embodiment includes an upper plate 1341, a side plate 1342, and a lower plate 1343, and is inserted into the column body 1100 as a whole, so the upper plate ( 1341 and the side plate 1342 are in contact with the pillar body 1100, and the lower plate 1343 is exposed on the lower surface of the pillar body 1100. At this time, the lower end of the second reinforcing bar 1240 is inserted into the through-hole formed in the upper plate 1341, and the column connecting hardware is inserted by a nut 1345 and a washer 1346 fastened to the thread of the lower end of the second reinforcing bar 1240. 1340) is fixed stably. On the other hand, by inserting a fixing bolt (1344) for additionally fixing the side plate (1342) of the column connection hardware (1340) into the column body (1100) and fastening the end of the side plate (1342), the column connection hardware ( It is possible to prevent the side plate 1342 from being bent and separated by a load applied to the lower side of the 1340). In addition, a through hole is formed in the lower plate 1343 of the column connecting hardware 1340 into which the reinforcing bars of the column corresponding to the lower layer are inserted. At this time, since the lower end of the second reinforcing bar 1240 is inserted and fixed in the through hole formed in the upper plate 1341 during the manufacturing process of the precast concrete column, the through hole of the upper plate 1341 is the second reinforcing bar 1240 It is possible to fit the thickness of the. On the other hand, since the lower plate 1343 is fastened by inserting the reinforcing bar of the precast concrete column located at the bottom of the site, it is preferable to form a size that is more than the thickness of the reinforcing bar in order to control the position, and eventually the upper plate 1341 The through hole of the lower plate 1343 is formed larger than that of the through hole.

And as will be described in detail later, since the interior of the column connection hardware 1340 of this embodiment is empty and at least one surface is open to the outside of the column body 1100, the lower plate 1343 is screwed to the lower plate 1343. It is possible. At this time, the direction in which the column connection hardware 1340 is opened to the outside of the column body 1100 is controlled by the arrangement direction of the column connection hardware 1340, and is arranged at a right angle as shown above in FIG. Rather than one of 1342 being exposed and the instantaneous gap between the column connecting hardware 1340 being narrowed, it is preferable to arrange it obliquely as shown below in FIG. 4.

5 is a view for explaining a precast concrete beam according to an embodiment of the present invention, Figure 6 is an enlarged view of the end of the precast concrete beam.

Like precast concrete columns, precast concrete beams (2000) are beams (girders) applied to the precast reinforced concrete construction method manufactured in advance and installed in the field. The illustrated precast concrete beam includes a beam body 2100, a beam reinforcement 2200, and a beam connecting hardware 2300, and both ends are in the form of a twin beam connected to a precast concrete column.

The beam body 2100 is a body of a precast concrete beam manufactured including reinforcing bars, and the configuration of a precast concrete column may be applied without limitation, except that a beam connecting hardware 2300 is installed at the end. However, in this embodiment, in order to increase the area of the precast concrete pillar 1000 that rises on the bracket 1120, in forming the extension part 2120 extending in the horizontal direction along the periphery of the precast concrete pillar 1000 , An extension part 2120 was formed only on one side. In this way, by applying the L-shaped structure in which the extension part 2120 is formed only on one side, the precast concrete beam 2000 is pre-installed in a horizontal movement through the direction in which the extension part 2120 is not formed. 1000) can be moved to the desired position. The extension part 2120 may play a role of a pouring barrier to prevent leakage of concrete when pouring concrete at the junction and a support when installing an upper precast concrete slab.

The beam reinforcement 2200 is horizontally inserted in the beam body 2100 in the longitudinal direction so that at least a portion of the beam reinforcement 2200 is exposed to the side of the beam body 2100. The beam reinforcement 2200 is positioned so as to surround the periphery of the column body 1100 together with the column hoop reinforcement, etc. after the installation of the precast concrete beam 2000, and the concrete poured on-site is poured while surrounding the reinforcing bar 2200. Therefore, it plays a role of firmly fixing the precast concrete column 1000 and the precast concrete beam 2000. However, as described above, in order to move the precast concrete beam 2000 between the precast concrete columns 1000 by applying the L-shaped structure in which the extension part 2120 is formed only on one side, the extension part The beam reinforcement 2200 exposed on the side where the 2120 is not formed is formed short enough not to be caught in the precast concrete column 1000, but a structure capable of extending the length of the reinforcing bar through the coupler 2210 is applied.

FIG. 11 is an enlarged view of connecting the reinforcing bars of precast concrete beams according to an embodiment of the present invention with a coupler.

In this embodiment, the end of the short beam reinforcing bar derived from the beam body 2100 and the end of the beam reinforcing bar for extension are respectively inserted into the coupler 2210 to extend, and the coupler 2210 connecting the beam reinforcing bar 2200 ) Has a thread formed therein, and a thread is formed on the surface of the reinforcing bar inserted into the coupler 2210 and is screwed to the coupler 2210. At this time, some clearance is formed in the threads of the coupler 2210 and the beam reinforcement, and auxiliary couplers 2211 and 2212 having internal threads on both sides of the coupler 2210 were added to compensate for this. As such, the auxiliary couplers 2211 and 2212 tighten both sides of the main coupler 2210 and push them, so that a problem due to the clearance between the main coupler 2210 and the reinforcing bar 2200 does not occur.

The prosthesis 2300 is installed at the end of the beam body 2100 that is placed on the bracket 1120 of the precast concrete column. At this time, in this embodiment, a protrusion 2110 is formed at the end of the beam body 2100, and at least a part of the prosthesis 2300 is installed on the protrusion 2110.

The beam connection reinforcing bar 2400 is inserted into the through hole of the beam connection hardware 2300, and the length at which the beam connection reinforcement 2400 protrudes can be adjusted until it is fixed at the site. A method of fastening and fixing the beam connection reinforcement 2400 to the beam connection hardware 2300 will be described in detail later.

The prosthesis 2300 of the present embodiment is a box or basket shape that has an empty interior and is opened in the upper direction of the beam body 2100. The prosthesis 2300 has a shape in which 4 of the 5 plates are inserted in contact with the beam body 2100, and a through hole through which the prosthesis reinforcement 2400 is fastened is formed on the side plate exposed to the outside. It is easy to install the through hole to be larger than the cross-section of the beam connection reinforcing bar 2400. When two or more beams connecting reinforcing bars 2400 are connected, an intermediate plate 2310 is installed inside to match each beam connecting reinforcing bar 2400. When the width of the prosthesis 2300 is widened by the intermediate plate 2310, a stable configuration is maintained even if the thickness of the steel plate is not made thick. Fixing members 2320 for fixing the position of the prosthesis 2300 inserted and installed in the beam body 2100 are inserted into the beam body 2100, and the fixing members 2320 are reinforcing bars for fixing as shown. It may be or is not particularly limited.

As will be described in detail later, since the interior of the prosthesis 2300 of the present embodiment is empty and the top surface is open to the outside of the beam body 2100, it is possible to perform a screwing operation on the prosthesis 2300. It is possible.

7 is a view for explaining a process of constructing precast concrete columns and beams according to an embodiment of the present invention.

As previously discussed, in the conventional precast method, in order to install the upper precast concrete pillar on the lower precast concrete pillar, the precast concrete beam is placed on the lower precast concrete pillar and the joint concrete and topping are performed by casting in place. After all the concrete was poured and hardened, the upper precast concrete column was installed.

On the other hand, the continuous construction method of precast concrete columns and beams of this embodiment is a beam connection protruding from the end of the prosthesis 2300 in the process of installing the precast concrete beam on the column body 1100a of the lower precast concrete column. With only the fixing of inserting the end of the reinforcing bar 2400 into the column body 1100a, without pouring the joint concrete and topping concrete, the column body 1100b of the upper precast concrete column is replaced with the lower precast concrete column. It is characterized in that it is fastened with a column connecting hardware (1340b) on the column body (1100a) of. That is, before performing the on-site casting for the junction of the precast concrete column 1000 and the precast concrete beam 2000, it is necessary to continuously construct only the precast concrete column 1000 and the precast concrete beam 2000. There are features.

8 is a view for explaining a state in which a precast concrete beam is fixed to a precast concrete column according to an embodiment of the present invention.

Installation of the conventional precast concrete beam 2000 was completed simply by raising the end of the beam body 2100 to the bracket 1120 of the installed precast concrete column. Since the precast concrete beam 2000 simply mounted in this way cannot withstand horizontal loads such as wind load, earthquake load, impact load, etc., concrete and topping concrete are poured at the junction of the precast concrete column 1000 and the precast concrete beam 2000 After stabilizing the precast concrete beam (2000), additional precast concrete columns were installed at the top.

On the other hand, in this embodiment, the precast concrete beam 2000 is inserted into the precast concrete column 1000 by inserting the beam connecting reinforcing bar 2400 protruding from the end of the precast concrete beam by being inserted into the through hole of the beam connecting hardware 2300. Because it is fixed, the precast concrete beam 2000 can be stably installed without pouring the joint concrete and topping concrete. Specifically

In a state where the end of the beam connection reinforcing bar 2400 is fitted and fixed to the coupler 1400 inserted into the surface of the precast concrete column 1000, the position by screwing the beam connection reinforcing bar 2400 to the prosthesis hardware 2300 Is fixed. As shown, when a nut 2330 and a washer 2340 are used for the reinforcing rod 2400 inserted in the through hole of the prosthesis 2300, the screws are fastened at both sides of the prosthesis 2300. The position of the connection reinforcing bar 2400 is fixed.

In a state where the beam connection reinforcement 2400 is screwed to the beam connection hardware 2300 and the position is fixed, the beam connection reinforcement 2400 protruding from both ends of the precast concrete beam is attached to the coupler 1400 of the column body 1100. It is difficult to fit. In this embodiment, the precast concrete beam is placed on the bracket 1120 while the beam connecting reinforcing bar 2400 is not screwed, and the end of the beam connecting reinforcing bar 2400 at the site is a coupler 1400 of the column body 1100. ), and then fix the position by screwing the beam connection reinforcing bar (2400) to the beam connection hardware (2300).

Adjustment of the position of the prosthesis reinforcing bar 2400 and screwing with the prosthesis hardware 2300 can be easily performed in the field because the interior of the prosthesis hardware 2300 is empty and the upper surface is open. At this time, by applying a setback shape in which the end of the prosthesis 2300 is recessed inward than the end of the protrusion 2110, a space for screwing can be secured.

In addition, by installing a shim 2600 between the protrusion 2110 of the end of the beam where the prosthesis 2300 is installed and the precast concrete column 1000, it is possible to supplement the compressive force. The shim 2600 is a structure in which a plurality of steel plates are stacked and fitted to fit the gap between the protrusion 2110 at the end of the beam and the precast concrete column 1000. And after screwing the prostheses 2300 and the reinforcing bars 2400, a non-shrinkable mortar 2500 may be filled between the precast concrete column 1000 and the protrusion 2110, and the above-described prosthesis hardware It is easy to inject the non-shrink mortar 2500 by the setback type of (2300). The filling of the non-shrinkable mortar 2500 does not have to be performed immediately after installation of the precast concrete beam 2000, but may be performed later. In addition, when the setback shape of the prosthesis 2300 is applied, cutting is facilitated when cutting of the beam protrusion 2110 according to a construction error is required.

Meanwhile, a shear key 1500 may be installed to reduce the direct shear friction force of the non-shrinkable mortar 2500 and the surface of the precast concrete column 1000.

9 is a view for explaining a state in which precast concrete columns are fastened to each other according to an embodiment of the present invention.

If the column body 1100b of the upper precast concrete column is placed on the column body 1100a of the lower precast concrete column, the surface treatment is not possible among the reinforcing bars protruding upward from the column body 1100a of the lower precast concrete column. The first reinforcing bar is inserted into the sleeve among the lower coupling parts formed on the column body 1100b of the upper precast concrete column, and the second reinforcing bar 1240a with thread treatment is formed on the column body 1100b of the upper precast concrete column. Among the lower coupling portions, it is inserted into the through hole formed in the lower plate 1343b of the column connecting hardware. And the second reinforcing bar (1240a) of the column body (1100a) of the lower precast concrete column was connected to the lower plate (1343b) of the column body (1100b) of the upper precast concrete column by using nuts (1347b) and washers (1348b). Fix by screwing. This screw fastening can be easily carried out in the field, because the inside of the column connecting hardware 1340 is empty and is open toward the outside. The pillar body 1100b of the upper precast concrete column can be stably installed because the column connecting hardware is screwed to the four second reinforcing bars located at the corners of each of the four sections of the precast concrete column.

As described above, in this embodiment, by screwing the second reinforcing bar 1240 to the column connecting hardware 1340, the column body of the upper precast concrete column on top of the column body 1100a of the lower precast concrete column without pouring topping concrete It is possible to install (1100b), and in the end, in this embodiment, it is possible to first continuously construct the precast concrete column 1000 and the precast concrete beam 2000 before performing on-site casting of the joint concrete and topping concrete. .

At this time, as described above, since the precast concrete beam 2000 of this embodiment applies an L-shaped structure in which the extension part 2120 is formed only on one side, the precast concrete beam 2000 can be installed by moving in a horizontal direction. , After fastening the column body 1100b of the upper precast concrete column, it is possible to install the precast concrete beam 2000 on the column body 1100a of the lower precast concrete column.

On the other hand, for precast concrete pillars located in the middle among precast concrete pillars constituting a multi-layer, if the thickness around the bracket is made thin, it is easier to install the precast concrete beam 2000 by moving it in the horizontal direction. Lose.

10 is a view for explaining a method of filling the non-shrinkable mortar in the column connecting hardware of this embodiment.

As described above, since the interior of the column connecting hardware of this embodiment is empty, it can be broken by fastening a nut and a washer to the thread of the second reinforcing bar protruding upward of the lower precast concrete column. However, in the end, the interior of the column connecting hardware must be filled with mortar or concrete to complete the final finish. At this time, in the process of filling the space between the sleeve into which the first reinforcing bar is inserted and the precast concrete column of the lower layer and the precast concrete column of the upper layer, without filling the empty interior of the column connecting hardware by a separate process. 10 shows a method of filling the interior of the column connecting hardware with non-shrink mortar together. As shown, if the column connecting hardware is manufactured in a setback shape located about 20mm inside the outer surface of the column body, a casting barrier covering both the open surface and the setback part of the column connecting hardware is installed and then connected to the sleeve. When the non-shrinkable mortar is injected through the injection hole 1600, the non-shrinkable mortar not only fills the space between the sleeve and the precast concrete column of the lower layer and the precast concrete column of the upper layer, but also inside the column connecting hardware as indicated by the arrow. Is filled to.

The present invention has been described above through preferred embodiments, but the above-described embodiments are only illustrative of the technical idea of the present invention, and various changes are possible within the scope not departing from the technical idea of the present invention. Those of ordinary knowledge will understand. Therefore, the scope of protection of the present invention should be interpreted not by specific embodiments, but by the matters described in the claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

1000: precast concrete pillar
1100: column body 1120: bracket
1200: column reinforcement 1220: first reinforcement
1240: second reinforcing bar 1300: lower coupling portion
1320: sleeve 1340: column connecting hardware
1341: top plate 1342: side plate
1343: lower plate 1344: fixing bolt
1400: coupler 1500: shear key
2000: precast concrete beam
2100: beam body 2110: protrusion
2120: extension 2200: beam reinforcement
2210: coupler 2300: prosthesis hardware
2310: intermediate plate 2320: fixing member
2400: beam connecting reinforcement 2500: non-shrink mortar
2600: shim

Claims (7)

Precast concrete beams manufactured in the factory and installed in the field,
A beam body made long in the horizontal direction;
Reinforcing bars installed horizontally on the beam body and partially exposed at both ends;
A prosthetic connecting hardware installed at both ends of the beam body, the interior is empty, the upper surface is opened to the outer surface of the beam body, and a through hole is formed at the end thereof; And
Precast concrete beam, characterized in that it comprises a beam connecting reinforcement positioned in the through hole.
The method according to claim 1,
A plurality of through-holes are formed at the ends of the prosthesis, and a reinforcing bar is inserted into each through-hole, and an intermediate plate for dividing the space in the longitudinal direction of the precast concrete beam is installed in the internal space of the prosthesis. Precast concrete beams characterized by.
The method according to claim 1,
Precast concrete beam, characterized in that a protrusion protruding a predetermined distance is formed at the center of both ends of the beam body, and at least a part of the prosthesis is installed on the protrusion.
The method of claim 3,
Precast concrete beam, characterized in that the end of the prosthesis is located inside a predetermined distance than the end of the protrusion.
The method according to claim 1,
Further comprising an extension extending in the horizontal direction at the edges of both ends of the beam body,
Precast concrete beam, characterized in that the extension portion is formed on only one of the edges of both ends of the beam body L-shaped end.
The method of claim 5,
Precast concrete beam, characterized in that the length of the reinforcing bar exposed to the side where the extension is not formed is shorter than that of the reinforcing bar exposed to the side where the extension is formed, and the length is extended by a coupler.
The method of claim 6,
The coupler has a thread formed therein, and is fastened with a thread formed at the ends of the connected reinforcing bars to extend the beam reinforcing bar,
Precast concrete beam, characterized in that it further comprises an auxiliary coupler that is screwed in addition to both sides of the coupler is formed with a thread therein.

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